JP4314481B2 - Color image processing apparatus, color image processing method, color image processing program, and storage medium - Google Patents

Description

  The present invention relates to a color image processing technique for converting an input color signal of three variables into an output color signal including a basic color, an achromatic color, and a special color.

  In the printing technology, red (R), green, and yellow (Y), magenta (M), cyan (C), and black (K: K) are used to express vivid colors that cannot be reproduced by four-color process printing. HiFi color printing is known in which color reproduction is performed by adding special colors composed of primary inks (G) and blue (B) and fluorescent ink to four colors of YMCK. As a color sample of a special color, a color sample of Pantone is known, and about 1000 special colors are defined.

  In recent years, in order to widen the color gamut and improve the color reproducibility of the RGB color space of digital cameras and the like in printers such as electrophotographic systems and inkjet systems, as in the case of printing, four colors of YMCK are used. Color reproduction is performed by adding 1 to 3 colors of RGB.

  As one of color conversion processing methods for creating a color signal for HiFi color printing, for example, a method called Kueppers Technique that is an extension of the UCR method is known.

  FIG. 8 is an explanatory diagram of an example of a color conversion processing method by Kueppers Technique. Kueppers Technique determines the achromatic component and the chromatic component using a technique similar to UCR. In Document 1, a white (W) component is generated from an RGB signal as an achromatic component by UCR processing, and then a CMY component is generated as a chromatic component by UCR processing. Here, in order to deal with the case of printing, it is assumed that a black (K) component is generated from the CMY signal as an achromatic component by UCR processing, and then an RGB component is generated as a chromatic component by UCR processing.

  FIG. 8A shows CMY signals when printing high-saturation red, and the values of the respective color signals are C = 50, M = 100, and Y = 100. A black (K) component, which is an achromatic component, is generated by UCR from these three color signals. As a result, as shown in FIG. 8B, K = 50 is generated as the black component. The generated achromatic component is removed from each color signal value, and C = 0, M = 50, and Y = 50.

  Further, the chromatic component is removed by UCR. In this example, since M = 50 and Y = 50 remain, R = 50 is generated. Then, the R component value is removed from the remaining color component values, and in this example, M = Y = 0. In this way, as shown in FIG. 8C, an output color signal of K = 50, R = 50, and others is obtained.

  As described above, Kueppers Technique is widely used because it uses a simple method called UCR processing. However, this Kueppers Technique can easily obtain a special color or a black or white achromatic signal, but has a problem in color reproducibility.

  For example, in the case shown in FIG. 8, the CMY color signal shown in FIG. 8A reproduces high saturation red, but the K signal is largely mixed in the R signal as shown in FIG. 8C. Therefore, there is a problem that a high saturation color by the R signal is not reproduced, and a dark and turbid color is reproduced. As described above, in the case of a highly saturated color, depending on the combination of input CMY signals, there is a problem that the saturation is deteriorated because a large amount of black (K) is introduced by the achromatic UCR process.

  FIG. 9 is an explanatory diagram of another example of color conversion processing by Kueppers Technique, and FIG. 10 is an explanatory diagram of an example of a color reproduction range in an output device. In the example shown in FIG. 9, a case where the color of the lowest brightness is shown with C = M = Y = 100 is shown. The CMY color signals shown in FIG. 9A are all replaced with K signals (= 100) by the achromatic UCR process, and become as shown in FIG. 9B. Of course, since there are no color components other than K, even if chromatic UCR processing is performed after that, K = 100 does not change. Therefore, the color signal of C = M = Y = 100 is converted into a single color K = 100 signal.

In an output device using general CMYK four colors, as can be seen with reference to FIG. 10, the color signal of C = M = Y = K = 100 has lightness compared to the signal of K = 100 of a single color. Lower. For example, in Japan Color 2001, which is standard printing, the brightness (L ^* ) of black single color 100% (K = 100) is 13, whereas the brightness of CMYK quaternary color 100% (C = M = Y = K = 100) is 7 and the color reproducibility difference in the low lightness region is very large. As described above, the color signal of C = M = Y = 100 is converted into a single color K = 100 signal in Kueppers Technique, and thus there is a problem that the color gamut in the low brightness part of the output device cannot be fully utilized. is there.

US Pat. No. 4,812,899

  The present invention has been made in view of the above-described circumstances, and when performing conversion to a color signal including an achromatic color and a special color, the color reproduction range at low brightness can be fully utilized, and the color reproducibility of high saturation can be utilized. It is an object of the present invention to provide a color image processing apparatus and a color image processing method with improved image quality. It is another object of the present invention to provide a color image processing program for causing a computer to execute such a color image processing method, and a storage medium storing such a color image processing program.

  The present invention provides a color image processing method for converting a three-variable input color signal into an output color signal including a basic color, an achromatic color and a special color, and a UCR process related to an achromatic color component from the three-variable input color signal, as in the prior art. To determine an achromatic signal of the output color signal, determine a first correction basic color signal obtained by subtracting a component corresponding to the achromatic color signal of the output color signal from the input color signal, and relate to the special color component from the first correction basic color signal. A spot color signal of the output color signal is determined by UCR processing, and a second correction basic color signal obtained by subtracting a portion corresponding to the spot color signal from the first correction basic color signal is determined.

  Further, in the present invention, the correction value of the basic color signal is determined from the determined achromatic color signal, the second correction basic color signal is corrected based on the correction value of the basic color signal, and the third correction basic color signal is determined. The determined achromatic color signal, the special color signal, and the third corrected basic color signal are output as output color signals.

  Alternatively, the correction value of the achromatic color signal is determined from the determined special color signal, the achromatic color signal is corrected by the correction value of the achromatic color signal, the corrected achromatic color signal, the determined special color signal and the second corrected basic color signal are obtained. The output color signal is output.

  The special color in the output color signal is at least one or three of red, green and blue, the basic color is at least one or three of yellow, magenta and cyan, and the achromatic color is black. Can do.

  Further, when the input color signal is a color signal in a device independent color space with three variables, the color signal in the device independent color space is converted in advance into a color signal corresponding to the basic color of the output color signal and then output as described above A process for determining a color signal can be performed. The color conversion characteristics when converting the color signal of the device-independent color space into the color signal corresponding to the basic color of the output color signal are the output colors based on the color signal corresponding to the basic color of the output color signal. A color determined from a relationship between the color measurement result and a color signal corresponding to a basic color of the output color signal by determining a signal, measuring the color chart obtained by inputting the output color signal to the output means, Use conversion characteristics.

  According to the present invention, since the basic color signal is corrected based on the achromatic color signal, the color in the low lightness region is corrected by, for example, correcting the achromatic color signal so that the lightness of the basic color signal is lowered in the low lightness region. Reproducibility can be improved and the color reproduction range at low brightness can be fully utilized. In addition, since the achromatic signal is corrected from the special color signal, for example, the reproducibility of the high saturation color can be improved by correcting the special color signal so that the lightness of the achromatic color signal is high in the high saturation region. There is.

  Furthermore, when the input color signal is a color signal in the device independent color space, the color signal in the device independent color space can be converted into a color signal corresponding to the basic color of the output color signal in the previous stage. The color conversion coefficient at that time is converted into the output color signal for the color signal corresponding to the basic color of the output color signal, the color chart is obtained from the output means, and the color corresponding to the basic color of the output color signal is measured. By obtaining from the relationship with the signal, colorimetric color reproduction can be guaranteed, and high-precision color conversion can be realized.

FIG. 1 is a block diagram showing an embodiment of the present invention. In the figure, 1 is a preceding color conversion unit, 2 is an achromatic UCR conversion unit, 3 is a chromatic UCR conversion unit, 4 is a CMY correction value determination unit, 5 is a CMY correction value addition unit, 6 is a K correction value determination unit, 7 Is a K correction value subtraction unit, and 8 is a color signal output unit. Here, an L ^* a ^* b ^* color signal, which is a device independent color signal, is input as an input color signal, and CMYKRGB color signals of CMY, RGB as a special color, and CMYKRGB color signals as special colors are output as basic colors of the output color signal. Will be described.

  The pre-stage color conversion unit 1 converts an input color signal in the device independent color space into a CMY color signal that is a basic color of the output color signal. The converted CMY color signal is transferred to the achromatic UCR converter 2. The pre-stage color conversion unit 1 can be configured by, for example, a three-dimensional direct lookup table with interpolation (hereinafter referred to as a DLUT). A method for obtaining the color conversion coefficient of the three-dimensional DLUT will be described later.

  The achromatic UCR conversion unit 2 performs an achromatic UCR process on the CMY signal and determines a K signal that is an achromatic signal. At the same time, the value of the K signal is subtracted from the value of the CMY signal to determine the C′M′Y ′ color signal that is the first correction basic color signal. The determined K signal is transferred to the CMY correction value determination unit 4 and the K correction value subtraction unit 7. The determined C′M′Y ′ color signal is transferred to the chromatic UCR converter 3.

  The chromatic UCR conversion unit 3 performs chromatic UCR processing on the C′M′Y ′ color signal to determine an RGB color signal which is a special color component. At the same time, the portion corresponding to the RGB color signal is subtracted from the C′M′Y ′ color signal to determine the C ″ M ″ Y ″ color signal, which is the second correction basic color signal. The data is transferred to the determination unit 6 and the color signal output unit 8. Further, the C "M" Y "color signal is transferred to the CMY correction value addition unit 5.

  The CMY correction value determination unit 4 determines a correction value ΔCΔMΔY of the CMY color signal from the K signal determined by the achromatic UCR conversion unit 2. The correction value ΔCΔMΔY is transferred to the CMY correction value adding unit 5. The CMY correction value determination unit 4 can be constituted by, for example, three one-dimensional LUTs (look-up tables) provided for each color signal.

  The CMY correction value addition unit 5 adds the correction value ΔCΔMΔY determined by the CMY correction value determination unit 4 to the C "M" Y "color signal determined by the chromatic UCR conversion unit 3 to obtain the third correction basic color signal. A certain C ′ ″ M ′ ″ Y ′ ″ color signal is determined, and the determined C ′ ″ M ′ ″ Y ′ ″ color signal is transferred to the color signal output unit 8.

  The K correction value determination unit 6 determines a correction value ΔK for the K signal from the RGB color signals determined by the chromatic UCR conversion unit 3. The determined correction value ΔK is transferred to the K correction value subtraction unit 7. As a method for determining the correction value ΔK, for example, the correction value can be determined using three LUTs corresponding to the R signal, the G signal, and the B signal, respectively, and the maximum value can be set as the correction value ΔK. . Of course, the correction value ΔK may be determined by other methods.

  The K correction value subtraction unit 7 subtracts the correction value ΔK determined by the K correction value determination unit 6 from the K signal determined by the achromatic UCR conversion unit 2 to determine the K ′ signal. The K ′ signal is transferred to the color signal output unit 8.

  The color signal output unit 8 includes a K ′ signal determined by the K correction value subtracting unit 7, an RGB color signal determined by the chromatic UCR conversion unit 3, and C ′ ″ M ″ determined by the CMY attended position adding unit 5. The “Y” color signal is output as an output color signal. For example, a color image can be printed by transferring it to an output device or the like.

  The above configuration will be further described. The pre-stage color conversion unit 1 is not necessary when, for example, a CMY color signal is input as an input color signal, and will be described later.

The achromatic UCR converter 2 determines the K signal and the C′M′Y ′ color signal from the CMY color signal by the achromatic UCR process. The UCR process at this time is given by the following equation. Here, Kmax represents the maximum value of the K signal, and α is a UCR rate related to the K signal. The UCR rate α may be given at a constant rate or in the form of a function with respect to Kmax.
Kmax = min (C, M, Y) (1)
K = α · Kmax (2)
C ′ = C−K (3)
M ′ = M−K (4)
Y ′ = Y−K (5)
The K signal obtained by this equation is transferred to the CMY correction value determination unit 4 and the K correction value subtraction unit 7, and the C′M′Y ′ color signal is transferred to the chromatic UCR conversion unit 3.

The chromatic UCR conversion unit 3 determines the RGB color signal and the C "M" Y "color signal, which are special colors, from the C'M'Y 'color signal by the chromatic UCR process. Here, A1 and A2 represent two color signals in which the value of the C′M′Y ′ color signal does not become zero when K = Kmax in Equations (3) to (5), and A3 Represents a color signal that can be reproduced by a combination of A1 and A2 among RGB color signals, for example, when the combination of A1 and A2 is Y'M ', Y'C', M'C ', A3 is R, G, and B. A3max represents the maximum value of the RGB signal, β is a UCR rate related to the RGB color signal, UCR rate β may be given as a constant rate, or given as a function for A3max. May be.
A3max = min (A1, A2) (6)
A3 = β · A3max (7)
A1 '= A1-A3 (8)
A2 '= A2-A3 (9)
Of the RGB color signals, color signals other than A3 are set to 0. Or you may perform a chromatic UCR process after performing this process. Also, two of the C′M′Y ′ color signals are replaced with A1 ′ and A2 ′ after UCR processing, and C′M ″ Y ”color signals including the color signals that have not been replaced are included. Of course, when UCR processing is performed a plurality of times, the three color signals of the C′M′Y ′ color signal may be replaced, and the obtained RGB color signal is converted into the K correction value determination unit 6. And the C ”M” Y ”color signal is transferred to the CMY correction value adding unit 5.

  The CMY correction value determination unit 4 determines the correction value ΔCΔMΔY. FIG. 2 is an explanatory diagram of a correction amount setting example in the CMY correction value determination unit 4. Only the conventional achromatic UCR process and chromatic UCR process have a problem that, for example, as shown in FIG. 9, the color gamut cannot be sufficiently used for colors with low brightness. For example, as described with reference to FIG. 10, by adding a CMY signal to the K signal rather than only the K signal, it is possible to reproduce a color with lower brightness. Therefore, in order to improve the color reproducibility in the low lightness region, for example, with respect to the color signal of C = M = Y = 100 of the input color signal expressing the minimum lightness, the output color signal has a single black color (K = 100, C = M = Y = 0), and a CMYK quaternary color may be obtained by adding a CMY signal. Therefore, correction for increasing the CMY signal may be performed for colors with low brightness.

  In this way, it is only necessary to add the CMY signal only in the vicinity of low brightness, for example, near the minimum brightness. Therefore, when the K signal is small, the correction value ΔCΔMΔY is set to zero to suppress the color change, the K signal starts to increase the correction value ΔCΔMΔY from a value close to the minimum brightness, and the desired minimum when the K signal is 100%. A correction value ΔCΔMΔY necessary for generating lightness may be determined. In the example shown in FIG. 2, the correction value ΔCΔMΔY starts to increase from K = 70, and ΔC = ΔM = ΔY = 100 when K = 100. However, the present invention is not limited to this, and the change in the correction value ΔCΔMΔY can be arbitrarily determined. For example, the correction value ΔCΔMΔY when K = 100 may be determined in consideration of the sum of the output color signals, and it is not necessary to set ΔC = ΔM = ΔY = 100. In the example shown in FIG. 2, the correction value is increased from K = 70. However, this value is also arbitrary, and the correction value to be increased is not limited to a linear function, and can be increased according to an arbitrary function.

  The correction value ΔCΔMΔY determined by the CMY correction value determination unit 4 as described above is transferred to the CMY correction value addition unit 5, and C ”M” determined by the chromatic UCR conversion unit 3 in the CMY correction value addition unit 5. Y ”color signal is added. When the addition result exceeds 100%, clipping is performed at 100%. By this correction, the C” M ”Y” color signal is corrected according to the brightness of the K signal. By using CMY together with K in the lightness region, it is possible to reproduce colors with lower lightness.

  The K correction value determination unit 6 determines the correction value ΔK. FIG. 3 is an explanatory diagram of a setting example of the correction amount in the K correction value determination unit 6. In the case where only conventional achromatic UCR processing and chromatic UCR processing can be reproduced with a high-saturation color by using, for example, a special color as shown in FIG. 8, the color becomes dark and turbid because K is included. There is. Such a problem becomes more prominent as the saturation is larger. In order to reproduce a high-saturation color more vividly, the value of the K signal generated from the high-saturation color may be reduced to increase the lightness. Therefore, in the example shown in FIG. 3, the correction value ΔK is set to increase as the RGB signal as the special color increases. Of course, for example, as shown in the graph of FIG. 2, the correction value may be increased after the RGB color signal exceeds a certain value, and the function for increasing the signal is not limited to a linear function.

  According to the relationship shown in FIG. 3, here, the correction amount ΔK is obtained for each of the R signal, G signal, and B signal determined by the chromatic UCR conversion unit 3. Then, the maximum value of the obtained three correction amounts ΔK can be determined as the correction value ΔK that is actually used and transferred to the K correction value calculation unit 7. Of course, the method of obtaining the correction amount ΔK from the RGB color signals is not limited to this example, and may be determined from the mutual relationship of the respective color signals.

  The K correction value subtraction unit 7 subtracts the correction value ΔK determined by the K correction value determination unit 6 in this way from the K signal determined by the achromatic UCR conversion unit 2, and outputs a color signal output unit as a K ′ signal. 8 is transferred. If the subtraction result is negative, it is clipped to zero. By this correction, it is possible to suppress the mixing of the K signal, which has been an obstacle when reproducing high-saturation colors using special colors, and to prevent the deterioration of saturation and enable bright and vivid color reproduction. .

  The color signal output unit 8 includes a C ′ ″ M ′ ″ Y ′ ″ color signal corrected by the CMY correction value adding unit 5, an RGB color signal that is a special color determined by the chromatic UCR conversion unit 3, and The K ′ signal corrected by the K correction value subtraction unit 7 is output as an output color signal.

  If only correction at low brightness is performed, the K correction value determination unit 6 and the K correction value subtraction unit 7 may be omitted. In this case, the K signal determined by the achromatic UCR converter 2 may be output instead of the K ′ signal as the output color signal. Further, if only correction with high saturation color is performed, the CMY correction value determination unit 4 and the CMY correction value addition unit 5 can be provided. In this case, instead of the C ′ ″ M ′ ″ Y ′ ″ color signal, the C ″ M ″ Y ″ color signal determined by the chromatic UCR converter 3 may be output as the output color signal.

  Finally, the pre-stage color conversion unit 1 will be described. In the processing after the achromatic UCR conversion unit 2, the pre-stage color conversion unit 1 converts a color signal other than the CMY color signal, which is the basic color of the output color signal, into a CMY color signal. Therefore, when a CMY color signal is input as an input color signal, it is possible to configure without providing the preceding color conversion unit 1. However, in addition to such simple color space conversion processing, the color reproducibility can be improved and a function for effectively utilizing the color gamut in the output device can be provided.

  FIG. 4 is a flowchart showing an example of a color conversion coefficient setting method in the pre-stage color conversion unit 1. In order to improve the color reproducibility in the output device and to effectively use the color gamut using the present invention, the color conversion coefficient used when performing color conversion in the pre-stage color conversion unit 1 is obtained as follows, for example. Can do. Here, a case where the pre-stage color conversion unit 1 is configured with a three-dimensional DLUT will be described.

  Before determining the color conversion coefficient of the pre-stage color conversion unit 1, conversion characteristics in each part after the achromatic UCR conversion unit 2 are determined. In S 11, C ′ ″ M, which is an output color signal that is input to the achromatic UCR conversion unit 2 and output from the color signal output unit 8 for any combination of the CMY color signals that are the output of the preceding color conversion unit 1. The '' 'Y' '' color signal, the K 'signal, and the RGB color signal are obtained.

In S12, a color chart corresponding to the output color signal obtained in S11 is printed by the output device, and the color chart is measured by a colorimeter to obtain a colorimetric value L ^* a ^* b ^* .

In S13, the data set of the CMY color signal input to the achromatic UCR conversion unit 2 in S11 and the colorimetric value L ^* a ^* b ^* obtained in S12 by the colorimetry of the color chart corresponding to the CMY color signal are obtained. As a teacher data, a neural network is trained, and the color reproduction characteristics of the output device (and the configuration including the configuration after the achromatic UCR conversion unit 2) are modeled (hereinafter referred to as a color conversion model). Here, a neural network is used to determine the color conversion model, but the present invention is not limited to this, and other types of color conversion models such as a higher-order polynomial model can also be applied.

In S14, the corresponding CMY color signal is determined from the address value (L ^* a ^* b ^* ) of the three-dimensional DLUT used as the pre-stage color conversion unit 1 using the color conversion model (here, a neural network) of the output device. . In S15, the CMY color signal determined in S14 is set to the corresponding address (grid point) of the three-dimensional DLUT. The processes of S14 and S15 are performed for each address value of the three-dimensional DLUT.

In general, it is difficult to match the colors reproduced by the output device by simple UCR processing. However, as described above, a color conversion model is created including the configuration after the achromatic UCR conversion unit 2 other than the previous color conversion unit 1 and the color reproduction characteristics of the output device, and the previous color conversion is performed using the color conversion model. By determining the color conversion coefficient of the three-dimensional DLUT of the unit 1, the L ^* a ^* b ^* color signal of the input color signal can be matched with the color printed by the output device, and the color reproduction of the output device can be achieved. It becomes possible to effectively use the area.

The above-described method for determining the color conversion coefficient of the pre-stage color conversion unit 1 is an example, and other methods may be used. Further, it is possible to adopt a configuration other than the three-dimensional DLUT as the pre-stage color conversion unit 1, and in this case, a color conversion coefficient determination method suitable for the configuration may be adopted. The same applies to an input color signal other than an L ^* a ^* b ^* color signal. For example, in the case of a color signal that depends on a device other than the output device that receives the output color signal, the color reproduction characteristics of the device. If the color conversion coefficient is determined in consideration of the above, color reproduction characteristics can be made substantially the same among a plurality of devices.

  The operation will be described below using a specific example. FIG. 5 is an explanatory diagram of a first specific example of the operation according to the embodiment of the present invention. FIG. 5 shows an example corresponding to FIG. 9 described above, that is, a case where the CMY color signal that is the output of the preceding color conversion unit 1 is C = M = Y = 100 (FIG. 5). (A)).

  In this case, as in the conventional technique Kuppers Technique, UCR processing is performed in the achromatic UCR conversion unit 2 to obtain K = 100 and C ′ = M ′ = Y ′ = 0 as shown in FIG. To be determined. Further, in the chromatic UCR conversion unit 3, since C ′ = M ′ = Y ′ = 0, even if UCR is performed, C ″ = M ″ = Y ″ = 0 remains (FIG. 5C). .

  On the other hand, the CMY correction value determination unit 4 determines the correction value ΔCΔMΔY = 100 from K = 100 according to the relationship shown in FIG. 2, for example (FIG. 5D). This correction value ΔCΔMΔY = 100 is transferred to the CMY correction value adding unit 5 and added with the C ″ M ″ Y ″ color signal (= 0) determined by the chromatic UCR conversion unit 3, and C ′ ″ = M ″. '= Y' '' = 100.

  In the K correction value determining unit 6, since the RGB signal of the special color is 0, the correction value ΔK is also 0 (FIG. 5E). Therefore, the K correction value subtracting unit 7 is the achromatic UCR converting unit 2. The K signal determined in step 1 becomes the K ′ signal as it is.

  In this way, the output color signal output from the color signal output unit 8 is a signal of C = M = Y = K = 100 as shown in FIG. 5 (F). As a result, a color signal of C = M = Y = 100 is output as a signal of C = M = Y = K = 100, which is lighter than the case of K single color obtained with the conventional Kepper's Technique. Color reproduction with a low quaternary color becomes possible. For example, if the color reproducibility of the output device is JapanColor2001, the minimum lightness obtained by the present invention is 6 lower than that of Kueppers Technique, which is the prior art, and the effect of improving the color reproducibility in the low lightness region according to the present invention is very large. . Since the spot color RGB color signal is 0, the illustration is omitted here.

  FIG. 6 is an explanatory diagram of a second specific example of the operation according to the embodiment of the present invention. FIG. 6 shows an example corresponding to FIG. 8 described above, that is, a case where the CMY color signal that is the output of the preceding color conversion unit 1 reproduces a vivid color by a special color. Here, as in FIG. 8, a case where C = 50 and M = Y = 100 is shown (FIG. 6A).

  As shown in FIG. 6B, the K (= 50) signal is determined by UCR processing in the achromatic UCR converter 2, and 50 is subtracted from C, M, and Y, and C ′ = 0, M ′ = Y. '= 50. Further, as shown in FIG. 6C, the spot color R (= 50) signal is determined by the UCR processing in the chromatic UCR conversion unit 3, and the R signal is subtracted from the M′Y ′ signal to obtain M ″ = Y ″. = 0. The C ″ color signal is also 0. In this way, K = 50 and R = 50 signals are obtained.

  On the other hand, the CMY correction value determination unit 4 determines the correction value ΔCΔMΔY according to, for example, the relationship shown in FIG. 2, but since K = 50, the correction value ΔCΔMΔY = 0 as shown in FIG. 6D. . Since C ″ = M ″ = Y ″ = 0, the output of the CMY correction value adding unit 5 is also C ′ ″ = M ′ ″ = Y ′ ″ = 0.

  In the K correction value determination unit 6, since the R signal of the spot color is 50, for example, the correction value ΔK = 50 is obtained by the relationship shown in FIG. 3 (FIG. 6E). Accordingly, the K correction value subtraction unit 7 subtracts the correction value ΔK = 50 from the K (= 50) signal determined by the achromatic UCR conversion unit 2 and outputs K ′ = 0.

  In this way, the output color signal output from the color signal output unit 8 is only the R (= 50) signal, as shown in FIG. In the present invention, the value of the K signal in the output color signal is small (0 in this example) compared to the conventional Kueppers Technique, so that vivid color reproduction with a special color is possible, and color reproducibility of the high saturation portion Will improve. In the example shown in FIG. 6, it is possible to reproduce bright red compared to the conventional case.

  As described above, the correction value of the CMY signal is determined for the K signal determined by the achromatic UCR conversion unit 2 in consideration of the minimum brightness of the output device, and correction is performed so that the CMY signal becomes large in the low brightness region. By doing so, the output color signal in the low lightness region is not a single black color but a CMYK quaternary color, and the color reproducibility in the low lightness region can be greatly improved as compared with the prior art. Further, with respect to the RGB signal determined by the chromatic UCR conversion unit 3, the RGB signal is used by determining the correction value of the K signal so that the value of the K signal becomes small in the high saturation portion where the RGB signal becomes large. It is possible to reduce the amount of black in the color, and it is possible to prevent the deterioration of saturation, which was a problem of the prior art.

  In the above description, the basic color of the output color signal is CMY, the achromatic color is K, and the special color is RGB. However, the present invention is not limited to this, and the present invention can be similarly applied to combinations of other colors, for example, the basic color is RGB, the achromatic color is W, and the special color is CMY.

  FIG. 7 is an explanatory diagram of an example of a computer program and a storage medium storing the computer program when the function of the color image processing apparatus or the color image processing method of the present invention is realized by the computer program. In the figure, 31 is a program, 32 is a computer, 41 is a magneto-optical disk, 42 is an optical disk, 43 is a magnetic disk, 44 is a memory, 51 is a magneto-optical disk apparatus, 52 is an optical disk apparatus, and 53 is a magnetic disk apparatus.

  Part or all of the configuration described in the above embodiment can be realized by a program 31 that can be executed by a computer. In that case, the program 31 and the data used by the program can be stored in a computer-readable storage medium. A storage medium is a signal format that causes a state of change in energy such as magnetism, light, electricity, etc. according to the description of a program to a reader provided in the hardware resources of a computer. Thus, the description content of the program can be transmitted to the reading device. For example, there are a magneto-optical disk 41, an optical disk 42 (including a CD and a DVD), a magnetic disk 43, a memory 44 (including an IC card and a memory card), and the like. Of course, these storage media are not limited to portable types.

  By storing the program 31 in these storage media and mounting these storage media in, for example, the magneto-optical disk device 51, the optical disk device 52, the magnetic disk device 53, or a memory slot (not shown) of the computer 32, the computer 31 The program 31 can be read to execute the function of the color image processing apparatus or the color image processing method of the present invention. Alternatively, a storage medium may be mounted or built in the computer 32 in advance, and the program 31 may be transferred to the computer 32 via a network, for example, and the program 31 may be stored in the storage medium and executed.

  Of course, some functions may be configured by hardware, or all may be configured by hardware. Alternatively, for example, it can be configured as one program together with the program of the image output apparatus and its driver program. Of course, in the case of application to other purposes, integration with a program for that purpose is also possible.

It is a block diagram which shows one Embodiment of this invention. It is explanatory drawing of the example of a setting of the correction amount in the CMY correction value determination part. It is explanatory drawing of the example of a setting of the correction amount in the K correction value determination part. 3 is a flowchart illustrating an example of a method for setting a color conversion coefficient in a pre-stage color conversion unit 1; It is explanatory drawing of the 1st specific example of the operation | movement in one Embodiment of this invention. It is explanatory drawing of the 2nd specific example of operation | movement in one Embodiment of this invention. It is explanatory drawing of an example of the storage medium which stored the computer program in the case of implement | achieving the function of the color image processing apparatus or color image processing method of this invention with a computer program, and the computer program. It is explanatory drawing of an example of the color conversion processing method by Kueppers Technique. It is explanatory drawing of another example of the color conversion process by Kueppers Technique. It is explanatory drawing of an example of the color reproduction range in an output device.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Previous stage color conversion part, 2 ... Achromatic UCR conversion part, 3 ... Chromatic UCR conversion part, 4 ... CMY correction value determination part, 5 ... CMY correction value addition part, 6 ... K correction value determination part, 7 ... K correction Value subtracting unit, 8 ... color signal output unit, 31 ... program, 32 ... computer, 41 ... magneto-optical disc, 42 ... optical disc, 43 ... magnetic disc, 44 ... memory, 51 ... magneto-optical disc device, 52 ... optical disc device, 53: Magnetic disk device.

Claims (18)

  In a color image processing apparatus that converts a three-variable input color signal into an output color signal including a basic color, an achromatic color, and a special color, the achromatic signal of the output color signal is converted from the three-variable input color signal by UCR processing relating to the achromatic color component. A first conversion means for determining a first corrected basic color signal determined by subtracting a component corresponding to the achromatic color signal of the output color signal from the input color signal; and the achromatic color signal determined by the first conversion means A second conversion means for determining a correction value of the basic color signal from the first correction basic color signal, a special color signal of the output color signal is determined from the first correction basic color signal by UCR processing relating to the special color component, and the first correction basic color signal is changed to the special color signal A third converting means for determining a second corrected basic color signal obtained by subtracting a corresponding portion, and a second corrected basic color signal determined by the third converting means is corrected by a correction value determined by the second converting means. A fourth conversion means for determining a third correction basic color signal; the achromatic color signal determined by the first conversion means; the spot color signal determined by the third conversion means; and the fourth conversion means determined by the fourth conversion means. 3. A color image processing apparatus which outputs a three-corrected basic color signal as an output color signal.   Further, a fifth conversion means for determining a correction value for the achromatic color signal from the spot color signal determined by the third conversion means, and a correction for determining the achromatic color signal determined by the first conversion means by the fifth conversion means. 6. The color image processing according to claim 1, further comprising: a sixth conversion unit that corrects the value based on the value, and outputting the achromatic signal corrected by the sixth conversion unit as an achromatic signal of the output color signal. apparatus.   In a color image processing apparatus that converts a three-variable input color signal into an output color signal including a basic color, an achromatic color, and a special color, the achromatic signal of the output color signal is converted from the three-variable input color signal by UCR processing relating to the achromatic color component. First conversion means for determining a first corrected basic color signal obtained by subtracting a component corresponding to the achromatic signal of the output color signal from the input color signal, and UCR processing relating to the special color component from the first corrected basic color signal A third color conversion unit that determines a special color signal of the output color signal and determines a second correction basic color signal obtained by subtracting a portion corresponding to the special color signal from the first correction basic color signal; and the third conversion unit A fifth conversion means for determining a correction value for the achromatic color signal from the spot color signal and a sixth conversion for correcting the achromatic color signal determined by the first conversion means with the correction value determined by the fifth conversion means. A color image processing apparatus having a stage and outputting the achromatic signal corrected by the sixth conversion means, the spot color signal determined by the third conversion means, and the second corrected basic color signal as output color signals .   4. The color image processing apparatus according to claim 1, wherein the special color in the output color signal includes at least one of three colors of red, green, and blue.   5. The color image processing apparatus according to claim 1, wherein the basic color in the output color signal includes at least one of three colors of yellow, magenta, and cyan.   6. The color image processing apparatus according to claim 1, wherein the achromatic color in the output color signal is black.   The input color signal is a three-variable device-independent color space color signal, and further, the color signal in the device-independent color space is converted into a color signal corresponding to the basic color of the output color signal before the first conversion means. 7. The color image processing apparatus according to claim 1, further comprising a seventh conversion unit.   The color conversion characteristic of the seventh conversion means is such that a color signal corresponding to the output of the seventh conversion means is input to the first conversion means to obtain an output color signal, and the output color signal is output to the output means. 8. The color chart obtained by input is colorimetrically determined based on a relationship between the colorimetric result and a color signal input to the first conversion unit. Color image processing device.   In a color image processing method for converting a three-variable input color signal into an output color signal including a basic color, an achromatic color, and a special color, the achromatic color signal of the output color signal is converted from the three-variable input color signal to the achromatic color component by UCR processing. The first correction basic color signal obtained by subtracting the component corresponding to the achromatic signal of the output color signal from the input color signal is determined by the first conversion means, and the correction value of the basic color signal is determined from the determined achromatic signal. Is determined by the second conversion means, the spot color signal of the output color signal is determined from the first corrected basic color signal by the UCR processing related to the spot color component, and the portion corresponding to the spot color signal is subtracted from the first corrected basic color signal. The second correction basic color signal is determined by the third conversion means, and the determined second correction basic color signal is corrected by the fourth conversion means based on the correction value of the basic color signal to determine the third correction basic color signal. And decision Color image processing method and outputting an achromatic signal and featured signal and the third corrected basic color signal as the output color signal.   Further, the correction value of the achromatic color signal is determined by the fifth conversion means from the determined spot color signal, the achromatic color signal is corrected by the sixth conversion means by the correction value of the achromatic color signal, and the corrected achromatic color signal is obtained. 10. The color image processing method according to claim 9, wherein the output color signal is output as an achromatic signal.   In a color image processing method for converting a three-variable input color signal into an output color signal including a basic color, an achromatic color, and a special color, the achromatic color signal of the output color signal is converted from the three-variable input color signal to the achromatic color component by UCR processing. The first correction basic color signal obtained by subtracting the component corresponding to the achromatic signal of the output color signal from the input color signal is determined by the first conversion means, and the first correction basic color signal is subjected to UCR processing relating to the special color component. A second color correction basic color signal obtained by subtracting a portion corresponding to the special color signal from the first correction basic color signal is determined by the third conversion means, and the achromatic color signal is determined from the determined special color signal. The correction value is determined by the fifth conversion means, the achromatic color signal is corrected by the sixth conversion means based on the correction value of the achromatic color signal, the corrected achromatic color signal, the determined special color signal and the second correction basics are corrected. Color image processing method and outputs the signal as an output color signal.   12. The color image processing method according to claim 9, wherein the special color in the output color signal includes at least one of three colors of red, green, and blue.   The color image processing method according to any one of claims 9 to 12, wherein the basic color in the output color signal includes at least one of three colors of yellow, magenta, and cyan.   The color image processing method according to claim 9, wherein the achromatic color in the output color signal is black.   When the input color signal is a color signal in a device independent color space having three variables, the color signal in the device independent color space is converted into a color signal corresponding to the basic color of the output color signal by the seventh color conversion means, The color image processing method according to claim 9, wherein an achromatic color signal and a first corrected basic color signal are determined.   The color conversion characteristics when converting the color signal of the device independent color space to the color signal corresponding to the basic color of the output color signal are determined based on the color signal corresponding to the basic color of the output color signal. The color chart obtained by inputting the output color signal to the output means is colorimetrically determined from the relationship between the colorimetric result and the color signal corresponding to the basic color of the output color signal. The color image processing method according to claim 15, wherein:   The color image processing program according to any one of claims 9 to 16, wherein the computer executes a process of converting a three-variable input color signal into an output color signal including a basic color, an achromatic color, and a special color. A color image processing program for causing a computer to execute an image processing method.   A computer-readable storage medium storing a color image processing program for causing a computer to execute a process of converting a three-variable input color signal into an output color signal including a basic color, an achromatic color, and a special color. A computer-readable storage medium storing a color image processing program for causing a computer to execute the color image processing method according to any one of 16.

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